Open AccessImproved parallel approximation of a class of integer programming problems
Author(s) -
Noga Alon,
Aravind Srinivasan
Publication year - 1997
Publication title -
algorithmica
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.647
H-Index - 78
eISSN - 1432-0541
pISSN - 0178-4617
DOI - 10.1007/bf02523683
Subject(s) - theory of computation , integer programming , bottleneck , generalization , approximation algorithm , integer (computer science) , class (philosophy) , mathematics , steiner tree problem , mathematical optimization , key (lock) , discrete mathematics , computer science , algorithm , combinatorics , artificial intelligence , mathematical analysis , computer security , programming language , embedded system
We present a method to derandomizeRNC algorithms, converting them toNC algorithms. Using it, we show how to approximate a class of NP-hard integer programming problems inNC, to within factors better than the current-bestNC algorithms (of Berger and Rompel and Motwaniet al.); in some cases, the approximation factors are as good as the best-known sequential algorithms, due to Raghavan. This class includes problems such as global wire-routing in VLSI gate arrays and a generalization of telephone network planning in SONET rings. Also for a subfamily of the “packing” integer programs, we provide the firstNC approximation algorithms; this includes problems such as maximum matchings in hypergraphs, and generalizations. The key to the utility of our method is that it involves sums ofsuperpolynomially many terms, which can however be computed inNC; this superpolynomiality is the bottleneck for some earlier approaches, due to Berger and Rompel and Motwaniet al.
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